Downhole display

ABSTRACT

Downhole display systems and methods. A display of one or more portions of a well log of a well during drilling may be displayed together with a display of one or more portions of one or more reference well logs, which may be presented as projected onto one or more planes, respectively. The logs may be segmented and correlated, with the segments or correlated portions displayed in different colors. A user may manipulate the display of the logs or log segments to assist in correlating them. The user may also manipulate the display so that the view provided of the wellbore and the projected logs changes in any one or all of three dimensions. In addition, the user may manipulate the display by navigating along the length of the borehole to view the projected logs at any point along the well path.

CROSS REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of priority of U.S. ProvisionalPatent Application Ser. No. 62/801,495, filed on Feb. 5, 2019, which ishereby incorporated by reference as if fully set forth herein.

BACKGROUND Field of the Disclosure

The present disclosure relates generally to drilling of wells for oiland gas production and, more particularly, to systems and methods forproviding a display of well information.

Description of the Related Art

Drilling a borehole for the extraction of minerals has become anincreasingly complicated operation due to the increased depth andcomplexity of many boreholes, including the complexity added bydirectional drilling. Drilling is an expensive operation and errors indrilling add to the cost and, in some cases, drilling errors maypermanently lower the output of a well for years into the future.Conventional technologies and methods may not adequately address thecomplicated nature of drilling, and may not be capable of gathering andprocessing various information from downhole sensors and surface controlsystems in a timely manner, in order to improve drilling operations andminimize drilling errors.

The determination of the well trajectory from a downhole survey mayinvolve various calculations that depend upon reference values andmeasured values. However, various internal and external factors mayadversely affect the downhole survey and, in turn, the determination ofthe well trajectory.

BRIEF DESCRIPTION OF THE DRAWINGS

For a more complete understanding of the present invention and itsfeatures and advantages, reference is now made to the followingdescription, taken in conjunction with the accompanying drawings, inwhich:

FIG. 1 is a depiction of a drilling system for drilling a borehole;

FIG. 2 is a depiction of a drilling environment including the drillingsystem for drilling a borehole;

FIG. 3 is a depiction of a borehole generated in the drillingenvironment;

FIG. 4 is a depiction of a drilling architecture including the drillingenvironment;

FIG. 5 is a depiction of rig control systems included in the drillingsystem;

FIG. 6 is a depiction of algorithm modules used by the rig controlsystems;

FIG. 7 is a depiction of a steering control process used by the rigcontrol systems;

FIG. 8 is a depiction of a graphical user interface provided by the rigcontrol systems;

FIG. 9 is a depiction of a guidance control loop performed by the rigcontrol systems;

FIG. 10 is a depiction of a controller usable by the rig controlsystems; and

FIG. 11 is a depiction of data mapping for a downhole display.

FIGS. 12 to 14 are depictions of a downhole display with gamma ray data;and

FIGS. 15 and 16 are depictions of a downhole display with geosteeringdata.

DESCRIPTION OF PARTICULAR EMBODIMENT(S)

In the following description, details are set forth by way of example tofacilitate discussion of the disclosed subject matter. It should beapparent to a person of ordinary skill in the field, however, that thedisclosed embodiments are exemplary and not exhaustive of all possibleembodiments.

Throughout this disclosure, a hyphenated form of a reference numeralrefers to a specific instance of an element and the un-hyphenated formof the reference numeral refers to the element generically orcollectively. Thus, as an example (not shown in the drawings), device“12-1” refers to an instance of a device class, which may be referred tocollectively as devices “12” and any one of which may be referred togenerically as a device “12”. In the figures and the description, likenumerals are intended to represent like elements.

Drilling a well typically involves a substantial amount of humandecision-making during the drilling process. For example, geologists anddrilling engineers use their knowledge, experience, and the availableinformation to make decisions on how to plan the drilling operation, howto accomplish the drill plan, and how to handle issues that arise duringdrilling. However, even the best geologists and drilling engineersperform some guesswork due to the unique nature of each borehole.Furthermore, a directional human driller performing the drilling mayhave drilled other boreholes in the same region and so may have somesimilar experience. However, during drilling operations, a multitude ofinput information and other factors may affect a drilling decision beingmade by a human operator or specialist, such that the amount ofinformation may overwhelm the cognitive ability of the human to properlyconsider and factor into the drilling decision. Furthermore, the qualityor the error involved with the drilling decision may improve with largeramounts of input data being considered, for example, such as formationdata from a large number of offset wells. For these reasons, humanspecialists may be unable to achieve optimal drilling decisions,particularly when such drilling decisions are made under timeconstraints, such as during drilling operations when continuation ofdrilling is dependent on the drilling decision and, thus, the entiredrilling rig waits idly for the next drilling decision. Furthermore,human decision-making for drilling decisions can result in expensivemistakes, because drilling errors can add significant cost to drillingoperations. In some cases, drilling errors may permanently lower theoutput of a well, resulting in substantial long term economic losses dueto the lost output of the well.

Referring now to the drawings, Referring to FIG. 1, a drilling system100 is illustrated in one embodiment as a top drive system. As shown,the drilling system 100 includes a derrick 132 on the surface 104 of theearth and is used to drill a borehole 106 into the earth. Typically,drilling system 100 is used at a location corresponding to a geographicformation 102 in the earth that is known.

In FIG. 1, derrick 132 includes a crown block 134 to which a travelingblock 136 is coupled via a drilling line 138. In drilling system 100, atop drive 140 is coupled to traveling block 136 and may providerotational force for drilling. A saver sub 142 may sit between the topdrive 140 and a drill pipe 144 that is part of a drill string 146. Topdrive 140 may rotate drill string 146 via the saver sub 142, which inturn may rotate a drill bit 148 of a bottom hole assembly (BHA) 149 inborehole 106 passing through formation 102. Also visible in drillingsystem 100 is a rotary table 162 that may be fitted with a masterbushing 164 to hold drill string 146 when not rotating.

A mud pump 152 may direct a fluid mixture (e.g., drilling mud 153) froma mud pit 154 into drill string 146. Mud pit 154 is shown schematicallyas a container, but it is noted that various receptacles, tanks, pits,or other containers may be used. Drilling mud 153 may flow from mud pump152 into a discharge line 156 that is coupled to a rotary hose 158 by astandpipe 160. Rotary hose 158 may then be coupled to top drive 140,which includes a passage for drilling mud 153 to flow into borehole 106via drill string 146 from where drilling mud 153 may emerge at drill bit148. Drilling mud 153 may lubricate drill bit 148 during drilling and,due to the pressure supplied by mud pump 152, drilling mud 153 mayreturn via borehole 106 to surface 104.

In drilling system 100, drilling equipment (see also FIG. 5) is used toperform the drilling of borehole 106, such as top drive 140 (or rotarydrive equipment) that couples to drill string 146 and BHA 149 and isconfigured to rotate drill string 146 and apply pressure to drill bit148. Drilling system 100 may include control systems such as aWOB/differential pressure control system 522, a positional/rotarycontrol system 524, a fluid circulation control system 526, and a sensorsystem 528, as further described below with respect to FIG. 5. Thecontrol systems may be used to monitor and change drilling rig settings,such as the WOB or differential pressure to alter the ROP or the radialorientation of the toolface, change the flow rate of drilling mud, andperform other operations. Sensor system 528 may be for obtaining sensordata about the drilling operation and drilling system 100, including thedownhole equipment. For example, sensor system 528 may include MWD orlogging while drilling (LWD) tools for acquiring information, such astoolface and formation logging information, that may be saved for laterretrieval, transmitted with or without a delay using any of variouscommunication means (e.g., wireless, wireline, or mud pulse telemetry),or otherwise transferred to steering control system 168. As used herein,an MWD tool is enabled to communicate downhole measurements withoutsubstantial delay to the surface 104, such as using mud pulse telemetry,while a LWD tool is equipped with an internal memory that storesmeasurements when downhole and can be used to download a stored log ofmeasurements when the LWD tool is at the surface 104. The internalmemory in the LWD tool may be a removable memory, such as a universalserial bus (USB) memory device or another removable memory device. It isnoted that certain downhole tools may have both MWD and LWDcapabilities. Such information acquired by sensor system 528 may includeinformation related to hole depth, bit depth, inclination angle, azimuthangle, true vertical depth, gamma count, standpipe pressure, mud flowrate, rotary rotations per minute (RPM), bit speed, ROP, WOB, amongother information. It is noted that all or part of sensor system 528 maybe incorporated into a control system, or in another component of thedrilling equipment. As drilling system 100 can be configured in manydifferent implementations, it is noted that different control systemsand subsystems may be used.

Sensing, detection, measurement, evaluation, storage, alarm, and otherfunctionality may be incorporated into a downhole tool 166 or BHA 149 orelsewhere along drill string 146 to provide downhole surveys of borehole106. Accordingly, downhole tool 166 may be an MWD tool or a LWD tool orboth, and may accordingly utilize connectivity to the surface 104, localstorage, or both. In different implementations, gamma radiation sensors,magnetometers, accelerometers, and other types of sensors may be usedfor the downhole surveys. Although downhole tool 166 is shown insingular in drilling system 100, it is noted that multiple instances(not shown) of downhole tool 166 may be located at one or more locationsalong drill string 146.

In some embodiments, formation detection and evaluation functionalitymay be provided via a steering control system 168 on the surface 104.Steering control system 168 may be located in proximity to derrick 132or may be included with drilling system 100. In other embodiments,steering control system 168 may be remote from the actual location ofborehole 106 (see also FIG. 4). For example, steering control system 168may be a stand-alone system or may be incorporated into other systemsincluded with drilling system 100.

In operation, steering control system 168 may be accessible via acommunication network (see also FIG. 10), and may accordingly receiveformation information via the communication network. In someembodiments, steering control system 168 may use the evaluationfunctionality to provide corrective measures, such as a convergence planto overcome an error in the well trajectory of borehole 106 with respectto a reference, or a planned well trajectory. The convergence plans orother corrective measures may depend on a determination of the welltrajectory, and therefore, may be improved in accuracy using certainmethods and systems for improved drilling performance.

In particular embodiments, at least a portion of steering control system168 may be located in downhole tool 166 (not shown). In someembodiments, steering control system 168 may communicate with a separatecontroller (not shown) located in downhole tool 166. In particular,steering control system 168 may receive and process measurementsreceived from downhole surveys, and may perform the calculationsdescribed herein using the downhole surveys and other informationreferenced herein.

In drilling system 100, to aid in the drilling process, data iscollected from borehole 106, such as from sensors in BHA 149, downholetool 166, or both. The collected data may include the geologicalcharacteristics of formation 102 in which borehole 106 was formed, theattributes of drilling system 100, including BHA 149, and drillinginformation such as weight-on-bit (WOB), drilling speed, and otherinformation pertinent to the formation of borehole 106. The drillinginformation may be associated with a particular depth or anotheridentifiable marker to index collected data. For example, the collecteddata for borehole 106 may capture drilling information indicating thatdrilling of the well from 1,000 feet to 1,200 feet occurred at a firstrate of penetration (ROP) through a first rock layer with a first WOB,while drilling from 1,200 feet to 1,500 feet occurred at a second ROPthrough a second rock layer with a second WOB (see also FIG. 2). In someapplications, the collected data may be used to virtually recreate thedrilling process that created borehole 106 in formation 102, such as bydisplaying a computer simulation of the drilling process. The accuracywith which the drilling process can be recreated depends on a level ofdetail and accuracy of the collected data, including collected data froma downhole survey of the well trajectory.

The collected data may be stored in a database that is accessible via acommunication network for example. In some embodiments, the databasestoring the collected data for borehole 106 may be located locally atdrilling system 100, at a drilling hub that supports a plurality ofdrilling systems 100 in a region, or at a database server accessibleover the communication network that provides access to the database (seealso FIG. 4). At drilling system 100, the collected data may be storedat the surface 104 or downhole in drill string 146, such as in a memorydevice included with BHA 149 (see also FIG. 10). Alternatively, at leasta portion of the collected data may be stored on a removable storagemedium, such as using steering control system 168 or BHA 149, that islater coupled to the database in order to transfer the collected data tothe database, which may be manually performed at certain intervals, forexample.

In FIG. 1, steering control system 168 is located at or near the surface104 where borehole 106 is being drilled. Steering control system 168 maybe coupled to equipment used in drilling system 100 and may also becoupled to the database, whether the database is physically locatedlocally, regionally, or centrally (see also FIGS. 4 and 5). Accordingly,steering control system 168 may collect and record various inputs, suchas measurement data from a magnetometer and an accelerometer that mayalso be included with BHA 149.

Steering control system 168 may further be used as a surface steerablesystem, along with the database, as described above. The surfacesteerable system may enable an operator to plan and control drillingoperations while drilling is being performed. The surface steerablesystem may itself also be used to perform certain drilling operations,such as controlling certain control systems that, in turn, control theactual equipment in drilling system 100 (see also FIG. 5). The controlof drilling equipment and drilling operations by steering control system168 may be manual, manual-assisted, semi-automatic, or automatic, indifferent embodiments.

Manual control may involve direct control of the drilling rig equipment,albeit with certain safety limits to prevent unsafe or undesired actionsor collisions of different equipment. To enable manual-assisted control,steering control system 168 may present various information, such asusing a graphical user interface (GUI) displayed on a display device(see FIG. 8), to a human operator, and may provide controls that enablethe human operator to perform a control operation. The informationpresented to the user may include live measurements and feedback fromthe drilling rig and steering control system 168, or the drilling rigitself, and may further include limits and safety-related elements toprevent unwanted actions or equipment states, in response to a manualcontrol command entered by the user using the GUI.

To implement semi-automatic control, steering control system 168 mayitself propose or indicate to the user, such as via the GUI, that acertain control operation, or a sequence of control operations, shouldbe performed at a given time. Then, steering control system 168 mayenable the user to imitate the indicated control operation or sequenceof control operations, such that once manually started, the indicatedcontrol operation or sequence of control operations is automaticallycompleted. The limits and safety features mentioned above for manualcontrol would still apply for semi-automatic control. It is noted thatsteering control system 168 may execute semi-automatic control using asecondary processor, such as an embedded controller that executes undera real-time operating system (RTOS), that is under the control andcommand of steering control system 168. To implement automatic control,the step of manual starting the indicated control operation or sequenceof operations is eliminated, and steering control system 168 may proceedwith only a passive notification to the user of the actions taken.

In order to implement various control operations, steering controlsystem 168 may perform (or may cause to be performed) various inputoperations, processing operations, and output operations. The inputoperations performed by steering control system 168 may result inmeasurements or other input information being made available for use inany subsequent operations, such as processing or output operations. Theinput operations may accordingly provide the input information,including feedback from the drilling process itself, to steering controlsystem 168. The processing operations performed by steering controlsystem 168 may be any processing operation, as disclosed herein. Theoutput operations performed by steering control system 168 may involvegenerating output information for use by external entities, or foroutput to a user, such as in the form of updated elements in the GUI,for example. The output information may include at least some of theinput information, enabling steering control system 168 to distributeinformation among various entities and processors.

In particular, the operations performed by steering control system 168may include operations such as receiving drilling data representing adrill path, receiving other drilling parameters, calculating a drillingsolution for the drill path based on the received data and otheravailable data (e.g., rig characteristics), implementing the drillingsolution at the drilling rig, monitoring the drilling process to gaugewhether the drilling process is within a defined margin of error of thedrill path, and calculating corrections for the drilling process if thedrilling process is outside of the margin of error.

Accordingly, steering control system 168 may receive input informationeither before drilling, during drilling, or after drilling of borehole106. The input information may comprise measurements from one or moresensors, as well as survey information collected while drilling borehole106. The input information may also include a drill plan, a regionalformation history, drilling engineer parameters, downholetoolface/inclination information, downhole tool gamma/resistivityinformation, economic parameters, reliability parameters, among variousother parameters. Some of the input information, such as the regionalformation history, may be available from a drilling hub 410, which mayhave respective access to a regional drilling database (DB) 412 (seeFIG. 4). Other input information may be accessed or uploaded from othersources to steering control system 168. For example, a web interface maybe used to interact directly with steering control system 168 to uploadthe drill plan or drilling parameters.

As noted, the input information may be provided to steering controlsystem 168. After processing by steering control system 168, steeringcontrol system 168 may generate control information that may be outputto drilling rig 210 (e.g., to rig controls 520 that control drillingequipment 530, see also FIGS. 2 and 5). Drilling rig 210 may providefeedback information using rig controls 520 to steering control system168. The feedback information may then serve as input information tosteering control system 168, thereby enabling steering control system168 to perform feedback loop control and validation. Accordingly,steering control system 168 may be configured to modify its outputinformation to the drilling rig, in order to achieve the desiredresults, which are indicated in the feedback information. The outputinformation generated by steering control system 168 may includeindications to modify one or more drilling parameters, the direction ofdrilling, the drilling mode, among others. In certain operational modes,such as semi-automatic or automatic, steering control system 168 maygenerate output information indicative of instructions to rig controls520 to enable automatic drilling using the latest location of BHA 149.Therefore, an improved accuracy in the determination of the location ofBHA 149 may be provided using steering control system 168.

Referring now to FIG. 2, a drilling environment 200 is depictedschematically and is not drawn to scale or perspective. In particular,drilling environment 200 may illustrate additional details with respectto formation 102 below the surface 104 in drilling system 100 shown inFIG. 1. In FIG. 2, drilling rig 210 may represent various equipmentdiscussed above with respect to drilling system 100 in FIG. 1 that islocated at the surface 104.

In drilling environment 200, it may be assumed that a drill plan (alsoreferred to as a well plan) has been formulated to drill borehole 106extending into the ground to a true vertical depth (TVD) 266 andpenetrating several subterranean strata layers. Borehole 106 is shown inFIG. 2 extending through strata layers 268-1 and 270-1, whileterminating in strata layer 272-1. Accordingly, as shown, borehole 106does not extend or reach underlying strata layers 274-1 and 276-1. Atarget area 280 specified in the drill plan may be located in stratalayer 272-1 as shown in FIG. 2. Target area 280 may represent a desiredendpoint of borehole 106, such as a hydrocarbon producing area indicatedby strata layer 272-1. It is noted that target area 280 may be of anyshape and size, and may be defined using various different methods andinformation in different embodiments. In some instances, target area 280may be specified in the drill plan using subsurface coordinates, orreferences to certain markers, that indicate where borehole 106 is to beterminated. In other instances, target area may be specified in thedrill plan using a depth range within which borehole 106 is to remain.For example, the depth range may correspond to strata layer 272-1. Inother examples, target area 280 may extend as far as can berealistically drilled. For example, when borehole 106 is specified tohave a horizontal section with a goal to extend into strata layer 172 asfar as possible, target area 280 may be defined as strata layer 272-1itself and drilling may continue until some other physical limit isreached, such as a property boundary or a physical limitation to thelength of the drill string.

Also visible in FIG. 2 is a fault line 278 that has resulted in asubterranean discontinuity in the fault structure. Specifically, stratalayers 268, 270, 272, 274, and 276 have portions on either side of faultline 278. On one side of fault line 278, where borehole 106 is located,strata layers 268-1, 270-1, 272-1, 274-1, and 276-1 are unshifted byfault line 278. On the other side of fault line 278, strata layers268-2, 270-3, 272-3, 274-3, and 276-3 are shifted downwards by faultline 278.

Current drilling operations frequently include directional drilling toreach a target, such as target area 280. The use of directional drillinghas been found to generally increase an overall amount of productionvolume per well, but also may lead to significantly higher productionrates per well, which are both economically desirable. As shown in FIG.2, directional drilling may be used to drill the horizontal portion ofborehole 106, which increases an exposed length of borehole 106 withinstrata layer 272-1, and which may accordingly be beneficial forhydrocarbon extraction from strata layer 272-1. Directional drilling mayalso be used alter an angle of borehole 106 to accommodate subterraneanfaults, such as indicated by fault line 278 in FIG. 2. Other benefitsthat may be achieved using directional drilling include sidetracking offof an existing well to reach a different target area or a missed targetarea, drilling around abandoned drilling equipment, drilling intootherwise inaccessible or difficult to reach locations (e.g., underpopulated areas or bodies of water), providing a relief well for anexisting well, and increasing the capacity of a well by branching offand having multiple boreholes extending in different directions or atdifferent vertical positions for the same well. Directional drilling isoften not limited to a straight horizontal borehole 106, but may involvestaying within a strata layer that varies in depth and thickness asillustrated by strata layer 172. As such, directional drilling mayinvolve multiple vertical adjustments that complicate the trajectory ofborehole 106.

Referring now to FIG. 3, one embodiment of a portion of borehole 106 isshown in further detail. Using directional drilling for horizontaldrilling may introduce certain challenges or difficulties that may notbe observed during vertical drilling of borehole 106. For example, ahorizontal portion 318 of borehole 106 may be started from a verticalportion 310. In order to make the transition from vertical tohorizontal, a curve may be defined that specifies a so-called “build up”section 316. Build up section 316 may begin at a kick off point 312 invertical portion 310 and may end at a begin point 314 of horizontalportion 318. The change in inclination in build up section 316 permeasured length drilled is referred to herein as a “build rate” and maybe defined in degrees per one hundred feet drilled. For example, thebuild rate may have a value of 6°/100 ft., indicating that there is asix degree change in inclination for every one hundred feet drilled. Thebuild rate for a particular build up section may remain relativelyconstant or may vary.

The build rate used for any given build up section may depend on variousfactors, such as properties of the formation (i.e., strata layers)through which borehole 106 is to be drilled, the trajectory of borehole106, the particular pipe and drill collars/BHA components used (e.g.,length, diameter, flexibility, strength, mud motor bend setting, anddrill bit), the mud type and flow rate, the specified horizontaldisplacement, stabilization, and inclination, among other factors. Anoverly aggressive built rate can cause problems such as severe doglegs(e.g., sharp changes in direction in the borehole) that may make itdifficult or impossible to run casing or perform other operations inborehole 106. Depending on the severity of any mistakes made duringdirectional drilling, borehole 106 may be enlarged or drill bit 146 maybe backed out of a portion of borehole 106 and redrilled along adifferent path. Such mistakes may be undesirable due to the additionaltime and expense involved. However, if the built rate is too cautious,additional overall time may be added to the drilling process, becausedirectional drilling generally involves a lower ROP than straightdrilling. Furthermore, directional drilling for a curve is morecomplicated than vertical drilling and the possibility of drillingerrors increases with directional drilling (e.g., overshoot andundershoot that may occur while trying to keep drill bit 148 on theplanned trajectory).

Two modes of drilling, referred to herein as “rotating” and “sliding”,are commonly used to form borehole 106. Rotating, also called “rotarydrilling”, uses top drive 140 or rotary table 162 to rotate drill string146. Rotating may be used when drilling occurs along a straighttrajectory, such as for vertical portion 310 of borehole 106. Sliding,also called “steering” or “directional drilling” as noted above,typically uses a mud motor located downhole at BHA 149. The mud motormay have an adjustable bent housing and is not powered by rotation ofthe drill string. Instead, the mud motor uses hydraulic power derivedfrom the pressurized drilling mud that circulates along borehole 106 toand from the surface 104 to directionally drill borehole 106 in build upsection 316.

Thus, sliding is used in order to control the direction of the welltrajectory during directional drilling. A method to perform a slide mayinclude the following operations. First, during vertical or straightdrilling, the rotation of drill string 146 is stopped. Based on feedbackfrom measuring equipment, such as from downhole tool 166, adjustmentsmay be made to drill string 146, such as using top drive 140 to applyvarious combinations of torque, WOB, and vibration, among otheradjustments. The adjustments may continue until a toolface is confirmedthat indicates a direction of the bend of the mud motor is oriented to adirection of a desired deviation (i.e., build rate) of borehole 106.Once the desired orientation of the mud motor is attained, WOB to thedrill bit is increased, which causes the drill bit to move in thedesired direction of deviation. Once sufficient distance and angle havebeen built up in the curved trajectory, a transition back to rotatingmode can be accomplished by rotating the drill string again. Therotation of the drill string after sliding may neutralize thedirectional deviation caused by the bend in the mud motor due to thecontinuous rotation around a centerline of borehole 106.

Referring now to FIG. 4, a drilling architecture 400 is illustrated indiagram form. As shown, drilling architecture 400 depicts a hierarchicalarrangement of drilling hubs 410 and a central command 414, to supportthe operation of a plurality of drilling rigs 210 in different regions402. Specifically, as described above with respect to FIGS. 1 and 2,drilling rig 210 includes steering control system 168 that is enabled toperform various drilling control operations locally to drilling rig 210.When steering control system 168 is enabled with network connectivity,certain control operations or processing may be requested or queried bysteering control system 168 from a remote processing resource. As shownin FIG. 4, drilling hubs 410 represent a remote processing resource forsteering control system 168 located at respective regions 402, whilecentral command 414 may represent a remote processing resource for bothdrilling hub 410 and steering control system 168.

Specifically, in a region 401-1, a drilling hub 410-1 may serve as aremote processing resource for drilling rigs 210 located in region401-1, which may vary in number and are not limited to the exemplaryschematic illustration of FIG. 4. Additionally, drilling hub 410-1 mayhave access to a regional drilling DB 412-1, which may be local todrilling hub 410-1. Additionally, in a region 401-2, a drilling hub410-2 may serve as a remote processing resource for drilling rigs 210located in region 401-2, which may vary in number and are not limited tothe exemplary schematic illustration of FIG. 4. Additionally, drillinghub 410-2 may have access to a regional drilling DB 412-2, which may belocal to drilling hub 410-2.

In FIG. 4, respective regions 402 may exhibit the same or similargeological formations. Thus, reference wells, or offset wells, may existin a vicinity of a given drilling rig 210 in region 402, or where a newwell is planned in region 402. Furthermore, multiple drilling rigs 210may be actively drilling concurrently in region 402, and may be indifferent stages of drilling through the depths of formation stratalayers at region 402. Thus, for any given well being drilled by drillingrig 210 in a region 402, survey data from the reference wells or offsetwells may be used to create the drill plan, and may be used for improveddrilling performance. In some implementations, survey data or referencedata from a plurality of reference wells may be used to improve drillingperformance, such as by reducing an error in estimating TVD or aposition of BHA 149 relative to one or more strata layers, as will bedescribed in further detail herein. Additionally, survey data fromrecently drilled wells, or wells still currently being drilled,including the same well, may be used for reducing an error in estimatingTVD or a position of BHA 149 relative to one or more strata layers.

Also shown in FIG. 4 is central command 414, which has access to centraldrilling DB 416, and may be located at a centralized command center thatis in communication with drilling hubs 410 and drilling rigs 210 invarious regions 402. The centralized command center may have the abilityto monitor drilling and equipment activity at any one or more drillingrigs 210. In some embodiments, central command 414 and drilling hubs 412may be operated by a commercial operator of drilling rigs 210 as aservice to customers who have hired the commercial operator to drillwells and provide other drilling-related services.

In FIG. 4, it is particularly noted that central drilling DB 416 may bea central repository that is accessible to drilling hubs 410 anddrilling rigs 210. Accordingly, central drilling DB 416 may storeinformation for various drilling rigs 210 in different regions 402. Insome embodiments, central drilling DB 416 may serve as a backup for atleast one regional drilling DB 412, or may otherwise redundantly storeinformation that is also stored on at least one regional drilling DB412. In turn, regional drilling DB 412 may serve as a backup orredundant storage for at least one drilling rig 210 in region 402. Forexample, regional drilling DB 412 may store information collected bysteering control system 168 from drilling rig 210.

In some embodiments, the formulation of a drill plan for drilling rig210 may include processing and analyzing the collected data in regionaldrilling DB 412 to create a more effective drill plan. Furthermore, oncethe drilling has begun, the collected data may be used in conjunctionwith current data from drilling rig 210 to improve drilling decisions.As noted, the functionality of steering control system 168 may beprovided at drilling rig 210, or may be provided, at least in part, at aremote processing resource, such as drilling hub 410 or central command414.

As noted, steering control system 168 may provide functionality as asurface steerable system for controlling drilling rig 210. Steeringcontrol system 168 may have access to regional drilling DB 412 andcentral drilling DB 416 to provide the surface steerable systemfunctionality. As will be described in greater detail below, steeringcontrol system 168 may be used to plan and control drilling operationsbased on input information, including feedback from the drilling processitself. Steering control system 168 may be used to perform operationssuch as receiving drilling data representing a drill trajectory andother drilling parameters, calculating a drilling solution for the drilltrajectory based on the received data and other available data (e.g.,rig characteristics), implementing the drilling solution at drilling rig210, monitoring the drilling process to gauge whether the drillingprocess is within a margin of error that is defined for the drilltrajectory, or calculating corrections for the drilling process if thedrilling process is outside of the margin of error.

Referring now to FIG. 5, an example of rig control systems 500 isillustrated in schematic form. It is noted that rig control systems 500may include fewer or more elements than shown in FIG. 5 in differentembodiments. As shown, rig control systems 500 includes steering controlsystem 168 and drilling rig 210. Specifically, steering control system168 is shown with logical functionality including an autodriller 510, abit guidance 512, and an autoslide 514. Drilling rig 210 ishierarchically shown including rig controls 520, which provide securecontrol logic and processing capability, along with drilling equipment530, which represents the physical equipment used for drilling atdrilling rig 210. As shown, rig controls 520 include WOB/differentialpressure control system 522, positional/rotary control system 524, fluidcirculation control system 526, and sensor system 528, while drillingequipment 530 includes a draw works/snub 532, top drive 140, mud pumpingequipment 536, and MWD/wireline equipment 538.

Steering control system 168 represent an instance of a processor havingan accessible memory storing instructions executable by the processor,such as an instance of controller 1000 shown in FIG. 10. Also,WOB/differential pressure control system 522, positional/rotary controlsystem 524, and fluid circulation control system 526 may each representan instance of a processor having an accessible memory storinginstructions executable by the processor, such as an instance ofcontroller 1000 shown in FIG. 10, but for example, in a configuration asa programmable logic controller (PLC) that may not include a userinterface but may be used as an embedded controller. Accordingly, it isnoted that each of the systems included in rig controls 520 may be aseparate controller, such as a PLC, and may autonomously operate, atleast to a degree. Steering control system 168 may represent hardwarethat executes instructions to implement a surface steerable system thatprovides feedback and automation capability to an operator, such as adriller. For example, steering control system 168 may cause autodriller510, bit guidance 512 (also referred to as a bit guidance system (BGS)),and autoslide 514 (among others, not shown) to be activated and executedat an appropriate time during drilling. In particular implementations,steering control system 168 may be enabled to provide a user interfaceduring drilling, such as the user interface 850 depicted and describedbelow with respect to FIG. 8. Accordingly, steering control system 168may interface with rig controls 520 to facilitate manual, assistedmanual, semi-automatic, and automatic operation of drilling equipment530 included in drilling rig 210. It is noted that rig controls 520 mayalso accordingly be enabled for manual or user-controlled operation ofdrilling, and may include certain levels of automation with respect todrilling equipment 530.

In rig control systems 500 of FIG. 5, WOB/differential pressure controlsystem 522 may be interfaced with draw works/snubbing unit 532 tocontrol WOB of drill string 146. Positional/rotary control system 524may be interfaced with top drive 140 to control rotation of drill string146. Fluid circulation control system 526 may be interfaced with mudpumping equipment 536 to control mud flow and may also receive anddecode mud telemetry signals. Sensor system 528 may be interfaced withMWD/wireline equipment 538, which may represent various BHA sensors andinstrumentation equipment, among other sensors that may be downhole orat the surface.

In rig control systems 500, autodriller 510 may represent an automatedrotary drilling system and may be used for controlling rotary drilling.Accordingly, autodriller 510 may enable automate operation of rigcontrols 520 during rotary drilling, as indicated in the drill plan. Bitguidance 512 may represent an automated control system to monitor andcontrol performance and operation drilling bit 148.

In rig control systems 500, autoslide 514 may represent an automatedslide drilling system and may be used for controlling slide drilling.Accordingly, autoslide 514 may enable automate operation of rig controls520 during a slide, and may return control to steering control system168 for rotary drilling at an appropriate time, as indicated in thedrill plan. In particular implementations, autoslide 514 may be enabledto provide a user interface during slide drilling to specificallymonitor and control the slide. For example, autoslide 514 may rely onbit guidance 512 for orienting a toolface and on autodriller 510 to setWOB or control rotation or vibration of drill string 146.

FIG. 6 illustrates one embodiment of control algorithm modules 600 usedwith steering control system 168. The control algorithm modules 600 ofFIG. 6 include: a slide control executor 650 that is responsible formanaging the execution of the slide control algorithms; a slide controlconfiguration provider 652 that is responsible for validating,maintaining, and providing configuration parameters for the othersoftware modules; a BHA & pipe specification provider 654 that isresponsible for managing and providing details of BHA 149 and drillstring 146 characteristics; a borehole geometry model 656 that isresponsible for keeping track of the borehole geometry and providing arepresentation to other software modules; a top drive orientation impactmodel 658 that is responsible for modeling the impact that changes tothe angular orientation of top drive 140 have had on the toolfacecontrol; a top drive oscillator impact model 660 that is responsible formodeling the impact that oscillations of top drive 140 has had on thetoolface control; an ROP impact model 662 that is responsible formodeling the effect on the toolface control of a change in ROP or acorresponding ROP set point; a WOB impact model 664 that is responsiblefor modeling the effect on the toolface control of a change in WOB or acorresponding WOB set point; a differential pressure impact model 666that is responsible for modeling the effect on the toolface control of achange in differential pressure (DP) or a corresponding DP set point; atorque model 668 that is responsible for modeling the comprehensiverepresentation of torque for surface, downhole, break over, and reactivetorque, modeling impact of those torque values on toolface control, anddetermining torque operational thresholds; a toolface control evaluator672 that is responsible for evaluating all factors impacting toolfacecontrol and whether adjustments need to be projected, determiningwhether re-alignment off-bottom is indicated, and determining off-bottomtoolface operational threshold windows; a toolface projection 670 thatis responsible for projecting toolface behavior for top drive 140, thetop drive oscillator, and auto driller adjustments; a top driveadjustment calculator 674 that is responsible for calculating top driveadjustments resultant to toolface projections; an oscillator adjustmentcalculator 676 that is responsible for calculating oscillatoradjustments resultant to toolface projections; and an autodrilleradjustment calculator 678 that is responsible for calculatingadjustments to autodriller 510 resultant to toolface projections.

FIG. 7 illustrates one embodiment of a steering control process 700 fordetermining an optimal corrective action for drilling. Steering controlprocess 700 may be used for rotary drilling or slide drilling indifferent embodiments.

Steering control process 700 in FIG. 7 illustrates a variety of inputsthat can be used to determine an optimum corrective action. As shown inFIG. 7, the inputs include formation hardness/unconfined compressivestrength (UCS) 710, formation structure 712, inclination/azimuth 714,current zone 716, measured depth 718, desired toolface 730, verticalsection 720, bit factor 722, mud motor torque 724, reference trajectory730, and angular velocity 726. In FIG. 7, reference trajectory 730 ofborehole 106 is determined to calculate a trajectory misfit in a step732. Step 732 may output the trajectory misfit to determine an optimalcorrective action to minimize the misfit at step 734, which may beperformed using the other inputs described above. Then, at step 736, thedrilling rig is caused to perform the optimal corrective action.

It is noted that in some implementations, at least certain portions ofsteering control process 700 may be automated or performed without userintervention, such as using rig control systems 700 (see FIG. 7). Inother implementations, the optimal corrective action in step 736 may beprovided or communicated (by display, SMS message, email, or otherwise)to one or more human operators, who may then take appropriate action.The human operators may be members of a rig crew, which may be locatedat or near drilling rig 210, or may be located remotely from drillingrig 210.

Referring to FIG. 8, one embodiment of a user interface 850 that may begenerated by steering control system 168 for monitoring and operation bya human operator is illustrated. User interface 850 may provide manydifferent types of information in an easily accessible format. Forexample, user interface 850 may be shown on a computer monitor, atelevision, a viewing screen (e.g., a display device) associated withsteering control system 168. In some embodiments, at least certainportions of user interface 850 may be displayed to and operated by auser of steering control system 168 on a mobile device, such as a tabletor a smartphone (see also FIG. 10). For example, steering control system168 may support mobile applications that enable user interface 850, orother user interfaces, to be used on the mobile device, for example,within a vicinity of drilling rig 210.

As shown in FIG. 8, user interface 850 provides visual indicators suchas a hole depth indicator 852, a bit depth indicator 854, a GAMMAindicator 856, an inclination indicator 858, an azimuth indicator 860,and a TVD indicator 862. Other indicators may also be provided,including a ROP indicator 864, a mechanical specific energy (MSE)indicator 866, a differential pressure indicator 868, a standpipepressure indicator 870, a flow rate indicator 872, a rotary RPM (angularvelocity) indicator 874, a bit speed indicator 876, and a WOB indicator878.

In FIG. 8, at least some of indicators 864, 866, 868, 870, 872, 874,876, and 878 may include a marker representing a target value. Forexample, markers may be set as certain given values, but it is notedthat any desired target value may be used. Although not shown, in someembodiments, multiple markers may be present on a single indicator. Themarkers may vary in color or size. For example, ROP indicator 864 mayinclude a marker 865 indicating that the target value is 50 feet/hour(or 15 m/h). MSE indicator 866 may include a marker 867 indicating thatthe target value is 37 ksi (or 255 MPa). Differential pressure indicator868 may include a marker 869 indicating that the target value is 200 psi(or 1,380 kPa). ROP indicator 864 may include a marker 865 indicatingthat the target value is 50 feet/hour (or 15 m/h). Standpipe pressureindicator 870 may have no marker in the present example. Flow rateindicator 872 may include a marker 873 indicating that the target valueis 500 gpm (or 31.5 L/s). Rotary RPM indicator 874 may include a marker875 indicating that the target value is 0 RPM (e.g., due to sliding).Bit speed indicator 876 may include a marker 877 indicating that thetarget value is 150 RPM. WOB indicator 878 may include a marker 879indicating that the target value is 10 klbs (or 4,500 kg). Eachindicator may also include a colored band, or another marking, toindicate, for example, whether the respective gauge value is within asafe range (e.g., indicated by a green color), within a caution range(e.g., indicated by a yellow color), or within a danger range (e.g.,indicated by a red color).

In FIG. 8, a log chart 880 may visually indicate depth versus one ormore measurements (e.g., may represent log inputs relative to aprogressing depth chart). For example, log chart 880 may have a Y-axisrepresenting depth and an X-axis representing a measurement such asGAMMA count 881 (as shown), ROP 883 (e.g., empirical ROP and normalizedROP), or resistivity. An autopilot button 882 and an oscillate button884 may be used to control activity. For example, autopilot button 882may be used to engage or disengage autodriller 510, while oscillatebutton 884 may be used to directly control oscillation of drill string146 or to engage/disengage an external hardware device or controller.

In FIG. 8, a circular chart 886 may provide current and historicaltoolface orientation information (e.g., which way the bend is pointed).For purposes of illustration, circular chart 886 represents threehundred and sixty degrees. A series of circles within circular chart 886may represent a timeline of toolface orientations, with the sizes of thecircles indicating the temporal position of each circle. For example,larger circles may be more recent than smaller circles, so a largestcircle 888 may be the newest reading and a smallest circle 889 may bethe oldest reading. In other embodiments, circles 889, 888 may representthe energy or progress made via size, color, shape, a number within acircle, etc. For example, a size of a particular circle may represent anaccumulation of orientation and progress for the period of timerepresented by the circle. In other embodiments, concentric circlesrepresenting time (e.g., with the outside of circular chart 886 beingthe most recent time and the center point being the oldest time) may beused to indicate the energy or progress (e.g., via color or patterningsuch as dashes or dots rather than a solid line).

In user interface 850, circular chart 886 may also be color coded, withthe color coding existing in a band 890 around circular chart 886 orpositioned or represented in other ways. The color coding may use colorsto indicate activity in a certain direction. For example, the color redmay indicate the highest level of activity, while the color blue mayindicate the lowest level of activity. Furthermore, the arc range indegrees of a color may indicate the amount of deviation. Accordingly, arelatively narrow (e.g., thirty degrees) arc of red with a relativelybroad (e.g., three hundred degrees) arc of blue may indicate that mostactivity is occurring in a particular toolface orientation with littledeviation. As shown in user interface 850, the color blue may extendfrom approximately 22-337 degrees, the color green may extend fromapproximately 15-22 degrees and 337-345 degrees, the color yellow mayextend a few degrees around the 13 and 345 degree marks, while the colorred may extend from approximately 347-10 degrees. Transition colors orshades may be used with, for example, the color orange marking thetransition between red and yellow or a light blue marking the transitionbetween blue and green. This color coding may enable user interface 850to provide an intuitive summary of how narrow the standard deviation isand how much of the energy intensity is being expended in the properdirection. Furthermore, the center of energy may be viewed relative tothe target. For example, user interface 850 may clearly show that thetarget is at 90 degrees but the center of energy is at 45 degrees.

In user interface 850, other indicators, such as a slide indicator 892,may indicate how much time remains until a slide occurs or how much timeremains for a current slide. For example, slide indicator 892 mayrepresent a time, a percentage (e.g., as shown, a current slide may be56% complete), a distance completed, or a distance remaining. Slideindicator 892 may graphically display information using, for example, acolored bar 893 that increases or decreases with slide progress. In someembodiments, slide indicator 892 may be built into circular chart 886(e.g., around the outer edge with an increasing/decreasing band), whilein other embodiments slide indicator 892 may be a separate indicatorsuch as a meter, a bar, a gauge, or another indicator type. In variousimplementations, slide indicator 892 may be refreshed by autoslide 514.

In user interface 850, an error indicator 894 may indicate a magnitudeand a direction of error. For example, error indicator 894 may indicatethat an estimated drill bit position is a certain distance from theplanned trajectory, with a location of error indicator 894 around thecircular chart 886 representing the heading. For example, FIG. 8illustrates an error magnitude of 15 feet and an error direction of 15degrees. Error indicator 894 may be any color but may be red forpurposes of example. It is noted that error indicator 894 may present azero if there is no error. Error indicator may represent that drill bit148 is on the planned trajectory using other means, such as being agreen color. Transition colors, such as yellow, may be used to indicatevarying amounts of error. In some embodiments, error indicator 894 maynot appear unless there is an error in magnitude or direction. A marker896 may indicate an ideal slide direction. Although not shown, otherindicators may be present, such as a bit life indicator to indicate anestimated lifetime for the current bit based on a value such as time ordistance.

It is noted that user interface 850 may be arranged in many differentways. For example, colors may be used to indicate normal operation,warnings, and problems. In such cases, the numerical indicators maydisplay numbers in one color (e.g., green) for normal operation, may useanother color (e.g., yellow) for warnings, and may use yet another color(e.g., red) when a serious problem occurs. The indicators may also flashor otherwise indicate an alert. The gauge indicators may include colors(e.g., green, yellow, and red) to indicate operational conditions andmay also indicate the target value (e.g., an ROP of 100 feet/hour). Forexample, ROP indicator 868 may have a green bar to indicate a normallevel of operation (e.g., from 10-300 feet/hour), a yellow bar toindicate a warning level of operation (e.g., from 300-360 feet/hour),and a red bar to indicate a dangerous or otherwise out of parameterlevel of operation (e.g., from 360-390 feet/hour). ROP indicator 868 mayalso display a marker at 100 feet/hour to indicate the desired targetROP.

Furthermore, the use of numeric indicators, gauges, and similar visualdisplay indicators may be varied based on factors such as theinformation to be conveyed and the personal preference of the viewer.Accordingly, user interface 850 may provide a customizable view ofvarious drilling processes and information for a particular individualinvolved in the drilling process. For example, steering control system168 may enable a user to customize the user interface 850 as desired,although certain features (e.g., standpipe pressure) may be locked toprevent a user from intentionally or accidentally removing importantdrilling information from user interface 850. Other features andattributes of user interface 850 may be set by user preference.Accordingly, the level of customization and the information shown by theuser interface 850 may be controlled based on who is viewing userinterface 850 and their role in the drilling process.

Referring to FIG. 9, one embodiment of a guidance control loop (GCL) 900is shown in further detail GCL 900 may represent one example of acontrol loop or control algorithm executed under the control of steeringcontrol system 168. GCL 900 may include various functional modules,including a build rate predictor 902, a geo modified well planner 904, aborehole estimator 906, a slide estimator 908, an error vectorcalculator 910, a geological drift estimator 912, a slide planner 914, aconvergence planner 916, and a tactical solution planner 918. In thefollowing description of GCL 900, the term “external input” refers toinput received from outside GCL 900, while “internal input” refers toinput exchanged between functional modules of GCL 900.

In FIG. 9, build rate predictor 902 receives external input representingBHA information and geological information, receives internal input fromthe borehole estimator 906, and provides output to geo modified wellplanner 904, slide estimator 908, slide planner 914, and convergenceplanner 916. Build rate predictor 902 is configured to use the BHAinformation and geological information to predict drilling build ratesof current and future sections of borehole 106. For example, build ratepredictor 902 may determine how aggressively a curve will be built for agiven formation with BHA 149 and other equipment parameters.

In FIG. 9, build rate predictor 902 may use the orientation of BHA 149to the formation to determine an angle of attack for formationtransitions and build rates within a single layer of a formation. Forexample, if a strata layer of rock is below a strata layer of sand, aformation transition exists between the strata layer of sand and thestrata layer of rock. Approaching the strata layer of rock at a 90degree angle may provide a good toolface and a clean drill entry, whileapproaching the rock layer at a 45 degree angle may build a curverelatively quickly. An angle of approach that is near parallel may causedrill bit 148 to skip off the upper surface of the strata layer of rock.Accordingly, build rate predictor 902 may calculate BHA orientation toaccount for formation transitions. Within a single strata layer, buildrate predictor 902 may use the BHA orientation to account for internallayer characteristics (e.g., grain) to determine build rates fordifferent parts of a strata layer. The BHA information may include bitcharacteristics, mud motor bend setting, stabilization and mud motor bitto bend distance. The geological information may include formation datasuch as compressive strength, thicknesses, and depths for formationsencountered in the specific drilling location. Such information mayenable a calculation-based prediction of the build rates and ROP thatmay be compared to both results obtained while drilling borehole 106 andregional historical results (e.g., from the regional drilling DB 412) toimprove the accuracy of predictions as drilling progresses. Build ratepredictor 902 may also be used to plan convergence adjustments andconfirm in advance of drilling that targets can be achieved with currentparameters.

In FIG. 9, geo modified well planner 904 receives external inputrepresenting a drill plan, internal input from build rate predictor 902and geo drift estimator 912, and provides output to slide planner 914and error vector calculator 910. Geo modified well planner 904 uses theinput to determine whether there is a more optimal trajectory than thatprovided by the drill plan, while staying within specified error limits.More specifically, geo modified well planner 904 takes geologicalinformation (e.g., drift) and calculates whether another trajectorysolution to the target may be more efficient in terms of cost orreliability. The outputs of geo modified well planner 904 to slideplanner 914 and error vector calculator 910 may be used to calculate anerror vector based on the current vector to the newly calculatedtrajectory and to modify slide predictions. In some embodiments, geomodified well planner 904 (or another module) may provide functionalityneeded to track a formation trend. For example, in horizontal wells, ageologist may provide steering control system 168 with a targetinclination as a set point for steering control system 168 to control.For example, the geologist may enter a target to steering control system168 of 90.5-91.0 degrees of inclination for a section of borehole 106.Geo modified well planner 904 may then treat the target as a vectortarget, while remaining within the error limits of the original drillplan. In some embodiments, geo modified well planner 904 may be anoptional module that is not used unless the drill plan is to bemodified. For example, if the drill plan is marked in steering controlsystem 168 as non-modifiable, geo modified well planner 904 may bebypassed altogether or geo modified well planner 904 may be configuredto pass the drill plan through without any changes.

In FIG. 9, borehole estimator 906 may receive external inputsrepresenting BHA information, measured depth information, surveyinformation (e.g., azimuth and inclination), and may provide outputs tobuild rate predictor 902, error vector calculator 910, and convergenceplanner 916. Borehole estimator 906 may be configured to provide anestimate of the actual borehole and drill bit position and trajectoryangle without delay, based on either straight line projections orprojections that incorporate sliding. Borehole estimator 906 may be usedto compensate for a sensor being physically located some distance behinddrill bit 148 (e.g., 50 feet) in drill string 146, which makes sensorreadings lag the actual bit location by 50 feet. Borehole estimator 906may also be used to compensate for sensor measurements that may not becontinuous (e.g., a sensor measurement may occur every 100 feet).Borehole estimator 906 may provide the most accurate estimate from thesurface to the last survey location based on the collection of surveymeasurements. Also, borehole estimator 906 may take the slide estimatefrom slide estimator 908 (described below) and extend the slide estimatefrom the last survey point to a current location of drill bit 148. Usingthe combination of these two estimates, borehole estimator 906 mayprovide steering control system 168 with an estimate of the drill bit'slocation and trajectory angle from which guidance and steering solutionscan be derived. An additional metric that can be derived from theborehole estimate is the effective build rate that is achievedthroughout the drilling process.

In FIG. 9, slide estimator 908 receives external inputs representingmeasured depth and differential pressure information, receives internalinput from build rate predictor 902, and provides output to boreholeestimator 906 and geo modified well planner 904. Slide estimator 908 maybe configured to sample toolface orientation, differential pressure,measured depth (MD) incremental movement, MSE, and other sensor feedbackto quantify/estimate a deviation vector and progress while sliding.

Traditionally, deviation from the slide would be predicted by a humanoperator based on experience. The operator would, for example, use along slide cycle to assess what likely was accomplished during the lastslide. However, the results are generally not confirmed until thedownhole survey sensor point passes the slide portion of the borehole,often resulting in a response lag defined by a distance of the sensorpoint from the drill bit tip (e.g., approximately 50 feet). Such aresponse lag may introduce inefficiencies in the slide cycles due toover/under correction of the actual trajectory relative to the plannedtrajectory.

In GCL 900, using slide estimator 908, each toolface update may bealgorithmically merged with the average differential pressure of theperiod between the previous and current toolface readings, as well asthe MD change during this period to predict the direction, angulardeviation, and MD progress during the period. As an example, theperiodic rate may be between 10 and 60 seconds per cycle depending onthe toolface update rate of downhole tool 166. With a more accurateestimation of the slide effectiveness, the sliding efficiency can beimproved. The output of slide estimator 908 may accordingly beperiodically provided to borehole estimator 906 for accumulation of welldeviation information, as well to geo modified well planner 904. Some orall of the output of the slide estimator 908 may be output to anoperator, such as shown in the user interface 850 of FIG. 8.

In FIG. 9, error vector calculator 910 may receive internal input fromgeo modified well planner 904 and borehole estimator 906. Error vectorcalculator 910 may be configured to compare the planned well trajectoryto an actual borehole trajectory and drill bit position estimate. Errorvector calculator 910 may provide the metrics used to determine theerror (e.g., how far off) the current drill bit position and trajectoryare from the drill plan. For example, error vector calculator 910 maycalculate the error between the current bit position and trajectory tothe planned trajectory and the desired bit position. Error vectorcalculator 910 may also calculate a projected bit position/projectedtrajectory representing the future result of a current error.

In FIG. 9, geological drift estimator 912 receives external inputrepresenting geological information and provides outputs to geo modifiedwell planner 904, slide planner 914, and tactical solution planner 918.During drilling, drift may occur as the particular characteristics ofthe formation affect the drilling direction. More specifically, theremay be a trajectory bias that is contributed by the formation as afunction of ROP and BHA 149. Geological drift estimator 912 isconfigured to provide a drift estimate as a vector that can then be usedto calculate drift compensation parameters that can be used to offsetthe drift in a control solution.

In FIG. 9, slide planner 914 receives internal input from build ratepredictor 902, geo modified well planner 904, error vector calculator910, and geological drift estimator 912, and provides output toconvergence planner 916 as well as an estimated time to the next slide.Slide planner 914 may be configured to evaluate a slide/drill ahead costequation and plan for sliding activity, which may include factoring inBHA wear, expected build rates of current and expected formations, andthe drill plan trajectory. During drill ahead, slide planner 914 mayattempt to forecast an estimated time of the next slide to aid withplanning. For example, if additional lubricants (e.g., fluorinatedbeads) are indicated for the next slide, and pumping the lubricants intodrill string 146 has a lead time of 30 minutes before the slide, theestimated time of the next slide may be calculated and then used toschedule when to start pumping the lubricants. Functionality for a losscirculation material (LCM) planner may be provided as part of slideplanner 914 or elsewhere (e.g., as a stand-alone module or as part ofanother module described herein). The LCM planner functionality may beconfigured to determine whether additives should be pumped into theborehole based on indications such as flow-in versus flow-backmeasurements. For example, if drilling through a porous rock formation,fluid being pumped into the borehole may get lost in the rock formation.To address this issue, the LCM planner may control pumping LCM into theborehole to clog up the holes in the porous rock surrounding theborehole to establish a more closed-loop control system for the fluid.

In FIG. 9, slide planner 914 may also look at the current positionrelative to the next connection. A connection may happen every 90 to 100feet (or some other distance or distance range based on the particularsof the drilling operation) and slide planner 914 may avoid planning aslide when close to a connection or when the slide would carry throughthe connection. For example, if the slide planner 914 is planning a 50foot slide but only 20 feet remain until the next connection, slideplanner 914 may calculate the slide starting after the next connectionand make any changes to the slide parameters to accommodate waiting toslide until after the next connection. Such flexible implementationavoids inefficiencies that may be caused by starting the slide, stoppingfor the connection, and then having to reorient the toolface beforefinishing the slide. During slides, slide planner 914 may provide somefeedback as to the progress of achieving the desired goal of the currentslide. In some embodiments, slide planner 914 may account for reactivetorque in the drill string. More specifically, when rotating isoccurring, there is a reactional torque wind up in drill string 146.When the rotating is stopped, drill string 146 unwinds, which changestoolface orientation and other parameters. When rotating is startedagain, drill string 146 starts to wind back up. Slide planner 914 mayaccount for the reactional torque so that toolface references aremaintained, rather than stopping rotation and then trying to adjust toan optimal toolface orientation. While not all downhole tools mayprovide toolface orientation when rotating, using one that does supplysuch information for GCL 900 may significantly reduce the transitiontime from rotating to sliding.

In FIG. 9, convergence planner 916 receives internal inputs from buildrate predictor 902, borehole estimator 906, and slide planner 914, andprovides output to tactical solution planner 918. Convergence planner916 is configured to provide a convergence plan when the current drillbit position is not within a defined margin of error of the planned welltrajectory. The convergence plan represents a path from the currentdrill bit position to an achievable and optimal convergence target pointalong the planned trajectory. The convergence plan may take account theamount of sliding/drilling ahead that has been planned to take place byslide planner 914. Convergence planner 916 may also use BHA orientationinformation for angle of attack calculations when determiningconvergence plans as described above with respect to build ratepredictor 902. The solution provided by convergence planner 916 definesa new trajectory solution for the current position of drill bit 148. Thesolution may be immediate without delay, or planned for implementationat a future time that is specified in advance.

In FIG. 9, tactical solution planner 918 receives internal inputs fromgeological drift estimator 912 and convergence planner 916, and providesexternal outputs representing information such as toolface orientation,differential pressure, and mud flow rate. Tactical solution planner 918is configured to take the trajectory solution provided by convergenceplanner 916 and translate the solution into control parameters that canbe used to control drilling rig 210. For example, tactical solutionplanner 918 may convert the solution into settings for control systems522, 524, and 526 to accomplish the actual drilling based on thesolution. Tactical solution planner 918 may also perform performanceoptimization to optimizing the overall drilling operation as well asoptimizing the drilling itself (e.g., how to drill faster).

Other functionality may be provided by GCL 900 in additional modules oradded to an existing module. For example, there is a relationshipbetween the rotational position of the drill pipe on the surface and theorientation of the downhole toolface. Accordingly, GCL 900 may receiveinformation corresponding to the rotational position of the drill pipeon the surface. GCL 900 may use this surface positional information tocalculate current and desired toolface orientations. These calculationsmay then be used to define control parameters for adjusting the topdrive 140 to accomplish adjustments to the downhole toolface in order tosteer the trajectory of borehole 106.

For purposes of example, an object-oriented software approach may beutilized to provide a class-based structure that may be used with GCL900 or other functionality provided by steering control system 168. InGCL 900, a drilling model class may be defined to capture and define thedrilling state throughout the drilling process. The drilling model classmay include information obtained without delay. The drilling model classmay be based on the following components and sub-models: a drill bitmodel, a borehole model, a rig surface gear model, a mud pump model, aWOB/differential pressure model, a positional/rotary model, an MSEmodel, an active drill plan, and control limits. The drilling modelclass may produce a control output solution and may be executed via amain processing loop that rotates through the various modules of GCL900. The drill bit model may represent the current position and state ofdrill bit 148. The drill bit model may include a three dimensional (3D)position, a drill bit trajectory, BHA information, bit speed, andtoolface (e.g., orientation information). The 3D position may bespecified in north-south (NS), east-west (EW), and true vertical depth(TVD). The drill bit trajectory may be specified as an inclination angleand an azimuth angle. The BHA information may be a set of dimensionsdefining the active BHA. The borehole model may represent the currentpath and size of the active borehole. The borehole model may includehole depth information, an array of survey points collected along theborehole path, a gamma log, and borehole diameters. The hole depthinformation is for current drilling of borehole 106. The boreholediameters may represent the diameters of borehole 106 as drilled overcurrent drilling. The rig surface gear model may represent pipe length,block height, and other models, such as the mud pump model,WOB/differential pressure model, positional/rotary model, and MSE model.The mud pump model represents mud pump equipment and includes flow rate,standpipe pressure, and differential pressure. The WOB/differentialpressure model represents draw works or other WOB/differential pressurecontrols and parameters, including WOB. The positional/rotary modelrepresents top drive or other positional/rotary controls and parametersincluding rotary RPM and spindle position. The active drill planrepresents the target borehole path and may include an external drillplan and a modified drill plan. The control limits represent definedparameters that may be set as maximums and/or minimums. For example,control limits may be set for the rotary RPM in the top drive model tolimit the maximum RPMs to the defined level. The control output solutionmay represent the control parameters for drilling rig 210.

Each functional module of GCL 900 may have behavior encapsulated withina respective class definition. During a processing window, theindividual functional modules may have an exclusive portion in time toexecute and update the drilling model. For purposes of example, theprocessing order for the functional modules may be in the sequence ofgeo modified well planner 904, build rate predictor 902, slide estimator908, borehole estimator 906, error vector calculator 910, slide planner914, convergence planner 916, geological drift estimator 912, andtactical solution planner 918. It is noted that other sequences may beused in different implementations.

In FIG. 9, GCL 900 may rely on a programmable timer module that providesa timing mechanism to provide timer event signals to drive the mainprocessing loop. While steering control system 168 may rely on timer anddate calls driven by the programming environment, timing may be obtainedfrom other sources than system time. In situations where it may beadvantageous to manipulate the clock (e.g., for evaluation and testing),a programmable timer module may be used to alter the system time. Forexample, the programmable timer module may enable a default time set tothe system time and a time scale of 1.0, may enable the system time ofsteering control system 168 to be manually set, may enable the timescale relative to the system time to be modified, or may enable periodicevent time requests scaled to a requested time scale.

Referring now to FIG. 10, a block diagram illustrating selected elementsof an embodiment of a controller 1000 for performing steering methodsand systems for improved drilling performance according to the presentdisclosure. In various embodiments, controller 1000 may represent animplementation of steering control system 168. In other embodiments, atleast certain portions of controller 1000 may be used for controlsystems 510, 512, 514, 522, 524, and 526 (see FIG. 5).

In the embodiment depicted in FIG. 10, controller 1000 includesprocessor 1001 coupled via shared bus 1002 to storage media collectivelyidentified as memory media 1010.

Controller 1000, as depicted in FIG. 10, further includes networkadapter 1020 that interfaces controller 1000 to a network (not shown inFIG. 10). In embodiments suitable for use with user interfaces,controller 1000, as depicted in FIG. 10, may include peripheral adapter1006, which provides connectivity for the use of input device 1008 andoutput device 1009. Input device 1008 may represent a device for userinput, such as a keyboard or a mouse, or even a video camera. Outputdevice 1009 may represent a device for providing signals or indicationsto a user, such as loudspeakers for generating audio signals.

Controller 1000 is shown in FIG. 10 including display adapter 1004 andfurther includes a display device 1005. Display adapter 1004 mayinterface shared bus 1002, or another bus, with an output port for oneor more display devices, such as display device 1005. Display device1005 may be implemented as a liquid crystal display screen, a computermonitor, a television or the like. Display device 1005 may comply with adisplay standard for the corresponding type of display. Standards forcomputer monitors include analog standards such as video graphics array(VGA), extended graphics array (XGA), etc., or digital standards such asdigital visual interface (DVI), definition multimedia interface (HDMI),among others. A television display may comply with standards such asNTSC (National Television System Committee), PAL (Phase AlternatingLine), or another suitable standard. Display device 1005 may include anoutput device 1009, such as one or more integrated speakers to playaudio content, or may include an input device 1008, such as a microphoneor video camera.

In FIG. 10, memory media 1010 encompasses persistent and volatile media,fixed and removable media, and magnetic and semiconductor media. Memorymedia 1010 is operable to store instructions, data, or both. Memorymedia 1010 as shown includes sets or sequences of instructions 1024-2,namely, an operating system 1012 and steering control 1014. Operatingsystem 1012 may be a UNIX or UNIX-like operating system, a Windows®family operating system, or another suitable operating system.Instructions 1024 may also reside, completely or at least partially,within processor 1001 during execution thereof. It is further noted thatprocessor 1001 may be configured to receive instructions 1024-1 frominstructions 1024-2 via shared bus 1002. In some embodiments, memorymedia 1010 is configured to store and provide executable instructionsfor executing GCL 900, as mentioned previously, among other methods andoperations disclosed herein.

As noted previously, steering control system 168 may support the displayand operation of various user interfaces, such as in a client/serverarchitecture. For example, steering control 1014 may be enabled tosupport a web server for providing the user interface to a web browserclient, such as on a mobile device or on a personal computer device. Inanother example, steering control 1014 may be enabled to support an appserver for providing the user interface to a client app, such as on amobile device or on a personal computer device. It is noted that in theweb server or the app server architecture, surface steering control 1014may handle various communications to rig controls 520 whilesimultaneously supporting the web browser client or the client app withthe user interface.

Geosteering

As used herein, “geosteering” refers to an optimal drilling andplacement of a borehole of a well (also referred to as a “wellbore”),such as borehole 106, with respect to one or more geological formations.Geosteering can be based on downhole geological and geophysical loggingmeasurements, together with 2D or 3D background geological models,rather than based on following a 3D drill plan in space. The objectiveof geosteering is usually to keep a directional wellbore within a targetzone, which is typically a geological formation or a specific part of aformation. Geosteering may be used to keep a wellbore in a particularsection of a reservoir to minimize gas or water breakthrough, and tomaximize economic production from the well. In addition, geosteering maybe useful to avoid certain formations, such as one in which a drill bitmay be more likely to get stuck, or to drill the wellbore so that thedrill bit penetrates a formation at a particular angle.

In the process of drilling a borehole, as described previously,geosteering may comprise adjusting the drill plan during drilling tostay in one or more geological target areas. The adjustments to thedrill plan in geosteering may be based on geological informationmeasured or logged while drilling and correlation of the measuredgeological information with a geological model of the formation. The jobof the directional driller is then to react to changes in the drill planprovided by geosteering, and to follow the latest drill plan.

A downhole tool used with geosteering will typically have azimuthal andinclination sensors (trajectory stations), along with a gamma raysensor. Other logging options may include neutron density, resistivity,look-ahead seismic, downhole pressure readings, among others. A largevolume of downhole data may be generated, especially by imaging tools,such that the data transmitted during drilling to the surface 104 viamud pulse and electromagnetic telemetry may be a selected fraction ofthe total generated downhole data. The downhole data that is nottransmitted to the surface 104 may be collected in a downhole memory,such as in downhole tool 166, and may be uploaded and decoded oncedownhole tool 166 is at the surface 104. The uploading of the downholedata at the surface 104 may be transmitted to remote locations fromdrilling rig 210 (see also FIG. 4).

Downhole Display

As noted previously, a display of various downhole log data and drillingdata may be shown to a user of geosteering control system 168 or anothercomputer system. The log data or drilling data shown to the user in thedownhole display may be acquired and displayed during drilling withoutdelay, or may be acquired previously and displayed after drilling iscomplete. The downhole display may be shown in various formats andarrangements, without limitation.

In one particular embodiment, a downhole display may be generated thatallows the user to graphically navigate along subterranean borehole 106.As the user navigates borehole 106, the log data or drilling data may beshown in the downhole display as plots versus MD along the actual pathof borehole 106. In some embodiments, such a downhole display of logdata and drilling data, such as may be provided by geosteering controlsystem 168, may be manipulated by a user providing input commandsthrough various types of user input devices, such as a touch screen, amouse, a joystick, a foot pedal, or a video game controller, indifferent embodiments. In addition, the downhole display may bemanipulated by two or more users simultaneously, such as by the use oftwo or more user input devices (e., game controllers) at the same time.The downhole display system described herein may be included orincorporated into the steering control system 168 or controller 1000 asare described above, or may be a separate computer system likecontroller 1000. The downhole display system may be coupled to a localor remote database, or both, and may allow for displaying relevantinformation locally at a drill site or a remote location, or both.

In certain embodiments, the user input device may be any one or more ofcommercially available game controllers, such as the Sony Playstationcontroller, the Nintendo Switch controller, the Wii Remote controller,and the Xbox game controller, which is commercially available fromMicrosoft Corporation. We believe that a game controller such as thisprovides a control device that is familiar and intuitive for most users,and therefore easier to use. In addition, we believe that such a gamecontroller as the user input device allows the user to quickly navigatealong the borehole and to quickly and easily adjust the view provided bythe display in any or all three dimensions. The ability to quickly andeasily manipulate the display provided is especially important when theuser is viewing a borehole as it is being drilled, as this helps allowthe user to make essentially real-time decisions about drillingoperations during drilling.

A game controller such as described above may be provided with one ormore accelerometers and one or more gyroscopes, as well as one or morevibrating devices. A game controller with these features is advantageousbecause it allows for the user to manipulate the downhole display bymoving the game controller in three dimensions, and in addition thevibrating devices can be used to alert the user when a condition occurs(e.g., the user has navigated to the end of the borehole).

Referring now to FIG. 11, the projection of downhole data by a downholedisplay system along a trajectory of borehole 106 in order to generatethe downhole display is described. The downhole data may be the log dataor drilling data that varies along a position of borehole 106, such asGR logs, MSE logs, magnetic logs, and/or resistivity logs, among othersdescribed herein. The downhole data shown in the downhole display may bethe same downhole data that is shown to an operator or another user atthe surface 104. The data provided to the downhole system in order togenerate the downhole display may be accessed from a database, such ascentral DB database 416, regional drilling DB 412, both, or anotherdatabase or databases. The database may be used to store downholereference data, such as one or more reference logs' data from portionsof a well that have already been drilled, one or more reference wells,or other sources that act as ‘fingerprints’ for matching downholemeasured data to correlate the location of the wellbore, usuallyrelative to one or more geological formations. It is noted that the sameor a different database may be used for the downhole display to recorduser data, such as previous interpretations of logs or log segments,templates for interpretations, and user input provided during aninterpretation, which may be stored by the user as templates andretrieved to perform correlations of well trajectories. The user datamay also be used to generate alerts, emails, reports, or othercommunication that can be auto-generated, for example. In addition, thedatabase used to store such information (e.g., previous logcorrelations) may also include interpretations from multiple users, whomay have differing interpretations of the log information, as well ascomments from one or more users on their own or others' interpretations.

Still referring to FIG. 11, a Kelly Bushing (KB) projection plane may bedefined as a vertical plane that orients beneath the geological KB pointfor a drilling rig at a drill site, and has a normal vector that pointsin a direction along a horizontal well trajectory extending from avertical section of the well. Accordingly, the downhole data, whetherreference data or measured data, may be projected from the KB projectionplane into a perpendicular projection plane, such as for horizontalsections of the wellbore trajectory. For example, a movable windowprojecting from the KB projection plane may be positioned along thedownhole data log at any desired position along the path of thewellbore. The movable window may be used as a common frame of referencefor both the KB projection plane (or the mapped projection plane) andthe logged data, which may represent a projection that can simplifypattern matching, such as recognition of a particular feature in thelogged data.

Performing pattern recognition and matching using the downhole displaycan aid humans in recognizing patterns that are characteristic offormations for detection of individual or specific formations, such asindicated in reference log data. For example, algorithms and machinelearning at large may be implemented with the downhole display forcorrelation, interpretation, kriging (also known as Gaussian processregression), and predictive analytics. In some implementations, thepattern recognition performed in conjunction with the downhole displaycan be based on human-recognizable patterns that are displayed to theuser and matched with an indication provided by the user. In someimplementations, the pattern recognition performed in conjunction withthe downhole display can be based on downhole data patterns that areautomatically detected and correlated, such as with measured surveydata. In particular, the pattern recognition may aid in identifyingdownhole data that indicate specific formation changes, such as GR logsthat identify a beginning or an end of a formation along borehole 106.The downhole data, such as GR logs, may enable the display of closestratigraphic layers, signatures, orientations, all along the variedgeometry of borehole 106, to enable better understanding by the user,along with improved visualization and interpretation of the downholedata. For example, the downhole display may be used to show and comparealternative projections of downhole data and geological interpretations,such as GR log interpretations from different users. As another example,the downhole display may reduce noise or interference in the displayedlog data projections, which may assist in better determining desired oroptimal build rates to land the trajectory of borehole 106 into thetarget area. As noted above, allowing a user to easily and quicklymanipulate the data via the downhole display provided by the downholedisplay system is advantageous because it minimizes the time requiredand increases the likelihood of a correct correlation of downhole data,thus allowing for faster and better decisions and adjustments inessentially real time during drilling.

As noted, the downhole display may be based on the KB projection planedisplay 1110 as illustrated in FIG. 11. The KB projection plane display1110 shown in FIG. 11 includes a segment of a log from the well beingdrilled. A geological formation 1100 is also shown. The formation 1100may be a target zone, but need not be. By changing the slope of the KBprojection plane 1110, the KB projection plane display 1110 may bemapped into various sections of borehole 106, including horizontalsections. In FIG. 11, a display 1101 of the log data is provided. Itshould be noted that the amplitude of the log 1101 increases just abovethe top of the formation 1100, and drops significantly to a minimumvalue upon reaching the top of the formation 1100. FIG. 11 also providesan exemplary display 1120 of the same log data as in 1110 and 1101 in aprojected well space 1120, as well as in a projection 1130 that isperpendicular to the formation 1100. The downhole display system can beprogrammed to allow a user to use the user input device (as describedabove) to manipulate the downhole display by switching between differentprojection modes (such as 1110, 1101, 1120, and 1130), and also bymoving along the length of the borehole 106, with the downhole displaysystem programmed to display a projection of the log corresponding theprojection mode selected by the user at a position along the logselected by the user. By moving quickly or slowly along the length ofthe borehole 106, the downhole display presented to the user providesthe same segment of log data from the well in varying shapes and sizes,thus allowing the user more easily find patterns that correlate with oneanother and/or with one or more reference logs.

After mapping the projection plane, noise reduction or noise eliminationmay be performed by the downhole display system on the downhole data,such as by filtering, smoothing, integrating, etc. In addition, anormalization of the amplitude of the downhole data may also beperformed. The X, Y, and Z coordinates (Northing, Easting, and TotalVertical Depth) can be isolated and distorted for each point, plane,thickness, and formation as a whole.

In order to perform correlation of the downhole data, different downholepositions (or indices) along the mapped downhole data log may beselected. Then, at a given downhole position, a section of the downholedata log may be mapped to the KB projection plane for correlation. It isnoted that the correlation may also be performed by mapping the downholedata in the KB projection plane to another projection. Such mapping maybe done automatically by the downhole display system, by a user usingthe downhole display system, or an initial mapping may be downautomatically by the downhole display system and then presented to auser for approval, modification, or rejection.

After mapping, certain adjustments or distortions, such as stretching orshrinking of the log along the X-axis (downhole position) or the Y-axis(amplitude) or both, may be performed to correlate the downhole data.For example, formation segments of reference downhole data may bedistorted (automatically or manually) to match markers, formation tops,and isopach signatures for the wellbore log or for other reference logs.The downhole display system may enable other similar correlations to beused and compared, such as previously performed log segment correlationsfor the same well, correlations from reference wells, or correlationsperformed by other users. As the downhole data log is adjusted anddistorted during the correlation for automatic interpolation for newmatches with isopachs markers, subregions of the plane top and formationslope may be defined to adjust the orientation. As the depth of borehole106 increases, different downhole reference data, such as from differentreference wells, may be used by the downhole display system, such asreference logs that are more pertinent to the formation(s) being drilledthrough. The downhole reference data may be selected manually by theuser or may be automatically selected by the downhole display systembased on a numerical confidence rating. When the selected downholereference data does not correspond to the downhole log data, variousdownhole data patterns from alternative reference wells may beconcatenated together to generate an expected formation log, 3D krigingplane, or to change the drill plan. Existing seismic or terrain modelsof the formation(s) of interest can help to accentuate the mapping, andmay be referenced with the numerical confidence level. Consistentreference log values while drilling may be taken by the downhole displaysystem as an indication that the formation geology and the reference logvalues are closely related, and may be directly mapped in a particularand homogeneous formation. A collection of wells interpreted may providea representation of an entire geological region or basin. Dataperpendicular to the formation structure may help to determine thegeometry of the formation. Fault or dip changes can transfer from thereference data log at the offset of KB, mapped mathematically by thedownhole display system to the original KB log, and would initiallypresume to be the same distance/thickness of formations. The offsetpoints of KB indicators may be continuously interpolated to indicatorsin the formation using a derived geometry by the downhole displaysystem. The reference data log readings can be inverted on both mirrorplanes, the KB projection plane, and the formation perpendicular plane,to show juxtaposing formation mapping and the original KB log on thedownhole display. Automatic mapping to show where the highs and lows ofthe formation or formations of interest are can be visually presentedfor multiple wells across the user interface with a numerical and 3Dvisualization/interpretation.

With the downhole display system, a user can select an inflection pointalong borehole 106 shown on the downhole display, to attempt tocorrelate the reference data log by manipulation with the measureddownhole data. As noted, this is typically done for a segment of thewellbore, but the length of the wellbore segment or log segment involvedcan be automatically selected by the downhole display system (e.g.,every ten or twenty feet of measured depth, or every hour of drillingtime) or can be manually selected by the user, such as by using agraphic user interface and user input device to select segment startingand ending points for the wellbore or for the log from a display of thewellbore or log, respectively, such as with a mouse click, a touch pad,or an input from a game controller as the user input device. In someimplementations, continuous operation of matching and correlation may beselected and performed. As noted, when the user is evaluating particularsections of borehole 106 and the corresponding log information, the usercan use the downhole display system to save section segments to analyzeat a later time, such as by using the database to save the same.Additionally, the user can use the system to create and add tags oncertain segments of the downhole reference logs to save in the databaseto search later or to include for predictive analytics and machinelearning. The user can use the system to also add in daily drillingoperations via depth-based information to indicate when drilling occursand when steering activities may be postponed, or the user may activateautomatic notifications or alerts for the same so that others involvedin the drilling operations receive such information. The user can alsouse the downhole display system to orient 3D representations of thewellbore and the log information to match 2D representations.

In order to interpret data shown using the downhole display, the user,such as a geologist, geosteerer, drilling engineer, directional driller,etc., can make decisions for how to position borehole 106 based onreference data such as reference logs and/or make changes to the currentdrill plan, which may be stored in a database accessible by the downholedisplay system. The drill plan may be accordingly shifted in bulk or bysegments by use of various methods including, but not limited to,trigonometry, based on the interpretation of the log data from thewellbore 106. The downhole display system may suggest drillingparameters and define formation tops via machine learning. In thedownhole display system, different offset wells can be weighted toassign a priority for interpretation, while different correlationchoices can also be weighted differently when generating interpolationsfrom other correlations or from other weighted numerical confidencelevels. In the downhole display system, reference log data projectionsmay be inverted to the KB plane as a check and confirmation.

As noted, the downhole display system may also be enabled to support orperform machine learning algorithms. For example, machine learning maybe used to characterize non-homogeneous formation compositions. The datainput into machine learning algorithms used for the downhole display maybe used to derive a driller's interpretation for log representations,such as in 3D. The reference log data patterns may help to identifystringers, faults, and create warnings for possible drilling-dysfunctionencounters, including determining a stop-drilling or slow-down decisionor condition, and provide alerts for such conditions and/orautomatically implement appropriate corrective action when suchconditions are detected, such as by reducing weight on bit, slowing rateof penetration, and/or adjusting other drilling parameters. The machinelearning algorithms may generate a projection to the build angle to landa curved section at the desired landing point. In addition, certaindrilling parameters may be suggested and formation tops may be definedusing the machine learning algorithms.

Using the downhole display system, the user can segment different logsand areas in the well that correspond to a cause-and-effect pattern thatcan be saved in the database for future identification, or for signalingto change the BHA or its drilling direction (or to adjust other drillingparameters). Automated suggestions for drilling, such as drilling tostay within a target formation, may be provided by the downhole displaysystem. Automated suggestions of predicted ROP, WOB, DifferentialPressure, and RPM ranges may be provided with the reference log datawhile drilling. In some embodiments, the downhole display system mayprovide such suggestions as control signals to one or more drilling rigcontrol systems or other equipment to automatically adjust drillingparameters in accordance with such suggestions. A suggested overlayplane for any expected drilling hazards may be generated by the system.Time frame predictions of drilling operations of the well being drilledbased on information from the offset wells may be provided and displayedon the display. Predictive time stamps on the wellbore display may bemarked and displayed by the system as well. The reference welloperations time stamp may be shown on the current well trajectory as aninformative and competitive indicator. Drilling parameters to mitigatethe predictive drilling dysfunctions or names of directional drillerswho have overcome recent and similar drilling dysfunctions may also beincluded in the database and provided on the display by the downholedisplay system.

The downhole display system allows manipulation of the well log byvarious adjustments. For example, a user can evaluate the reference logdata by using the user input device to change the view of the display bymoving along the KB projection plane and distorting the projectedreference log data in the formation and orientation back to a desiredposition, and can do so along any desired portion of the borehole 106 orthe entire length of the borehole 106 if desired. Formation layers maybe labeled alongside the TVD of borehole 106 in the display. Arepresentation of a steering window for high/low and left/right of thedrill plan may be displayed and included with the reference log data andwell log data correlation. Each data point of information from a log mayeffectively improve alignment relative to an axis. A user can add 2Dstand-alone reference data logs and interpretations in various dataformats (LAS, MS-Excel (Microsoft Corp.), CSV) to the database and thedownhole display system can transpose such reference data logs into a 3Dformat to stretch and fit to a desired downhole data log. A user can usethe downhole display system to update the formation layer model aroundborehole 106 from reference data logs and from inferred automatic andmanual log correlations. A user can also use the system to mergedatasets of different reference data log offsets to one continuousexpected reference data log projection. Auto segmentation for a steeringinterpretation based on past patterns may be provided by the downholedisplay system. Different formation segments may be zonally isolated tocorrelate and interpret, based on inserted completions plans. In thismanner, different portions of the well may be managed depending upon thesmoothness of borehole 106 for improved drilling, fracking, and/orproduction performance.

In some embodiments, more than one user may use the downhole displaysystem and relevant database or databases at the same time. For example,multiple users may use the system to interpret and maintain multipleversions of a particular downhole interpretations of data logssimultaneously. Multiple interpretations can be combined or keptseparate for cumulative analysis, such that resulting formation modelsmay be independent of single data sources. Multiple users may be activein a single session of the same virtual environment for communicationand collaboration. The downhole display system may be used to providemultiple users with one or more interpretations of one or more logsegments and allow one or more other users to comment, modify, or adjustthe interpretation. The system can also be used by multiple users foranalysis and editing of log correlations. Such sharing can be helpfulespecially because the system allows the multiple users to shareparticular views of an interpretation or correlation. In somesituations, a given view of a correlation of two log segments may beconclusive even when other views of the same two log segments are notclear.

The downhole display system may support kriging of various types ofreference log data. Isopachs of reference well(s) reference log datapatterns may be projected by the system as a future prediction of thereference log data in non-drilled sections. Patterning of non-homogenousformations such as striation, faults, dips, and homogeneous formationsmay be duplicated by the downhole display system in an X, Y, Z, size,shape, predicted pattern along borehole 106 and within a region or abasin. Adjustments to 3D data for the location of dips, faults, andother geological characteristics may be performed automatically by thedownhole display system.

The downhole display system supports manipulation of various features ofthe display by a user in some embodiments. An X, Y, Z pattern may beused for adjustments to factor in anomalies, such as for an invariablestriation thickness. Unexpected dips and faults may be accounted for bythe system by suggesting different kriging interpretations for a numberof possible correlations and the best fit can then be selected as thecorrect correlation. Certain distortions, such as stretching orshrinking a log along the X-axis (downhole position) or the Y-axis(amplitude) or both, may be performed automatically by the system toinfer formation structures downhole. Manipulations of the reference welllog data may be utilized by the downhole display system to control thetoolface orientation to a desired value. Distortion to X, Y, Zcoordinates, planes, formations, and basins, may be performed by theuser operating a user input device such as a game controller, mouse, orby using a program interface. The distortion may represent the change ofpercentage, numerical thickness, and may include a suggested automatedinterpretation.

The downhole display system may provide various interface features thatincorporate sensory design aspects including but not limited to visualimages, audio, haptic feedback, and temperature changes. Interfaces ofdifferent planes can be transparent to show information of but notlimited to multiple formation layers and reference well information.Different reference wells can be displayed with different colors fortheir corresponding data logs shown with the downhole display. Colorchanges to anti-collision ellipses of uncertainty and/or regions of atarget window surrounding the well borehole may be shown in green,yellow, and red. This may be helpful in the case of geosteering toquickly signal on a visual display how well the wellbore is placed in agiven location along the wellbore trajectory. In situations in which thewellbore being drilled in located in proximity to other wells, the colorshading of the ellipses of uncertainty is helpful to quickly andvisually signal to the user via the display if there are narrowingseparation factors and to signal the risk of a collision. Color changesto the drilling/geological window can also be used by the system toreflect different circumstances. The user can select different color andpattern display options for, but not limited, to reference log data,Differential Pressure, ROP, WOB, MSE, and RPM, among others. There canbe color changes when geological or drilling traces lay on top of oneanother to form another color using transparent or semitransparentlayering. The user can use the system to add alarm features if there isan overlap of reference data log signatures with the reference well inagreement or conflict.

FIGS. 12, 13, and 14 depict an example of the downhole display providedby an embodiment of the downhole display system. Specifically, FIGS. 12,13, and 14 depict a gamma ray reference log 1210 that is plotted along awellbore axis 1200. Although a blank background is shown, it is notedthat actual formation data may also be depicted in the background. Forexample, the display could include only a target formation, or it couldinclude a series of formations, and can include identifying informationfor the formation or formations of interest (e.g., Austin Chalk,Eagleford, etc.) Additionally, measured log data 1215 and 1220 from thewellbore are shown in two different colors, such as green and red. Forexample, one segment of the measured log data 1215 may be shown in greenif it has been previously correlated successfully, with a new or morerecent log data segment from measured log data 1215 shown in red toindicate that it still needs to be successfully correlated. Inparticular, FIGS. 12, 13, and 14 depict a 45° bend in the wellbore 1200and show how the measured log data 1215 and 1220 and the reference logdata 1210 can be displayed for a 45° angle of inclination. For example,either the reference log data 1210 or the measured log data 1215, 1220can be modified from being plotted against TVD for a vertical well to MDafter the 45° bend. In addition, FIG. 12 includes a log 1230. In thisexample, the log data 1230 illustrates a segment of the measured log asprojected onto the Kelly Bushing plane for the well.

Referring now to FIG. 13, additional detail of the downhole display isprovided. As illustrated in FIG. 13, portions of log 1215 overlap withportions of log 1220. By providing these two logs in different colors,it is easier to see the portions that have been correlated and theportions that have not, as well as the portions which do not overlapwith one another. In FIG. 13, the MD log 1240 for the well as projectedalong the well trajectory is also illustrated. FIG. 13 also illustratesa portion of the KB projection log 1230 and the target well path 1200.The downhole display system is programmed to allow a user to use theuser input device to zoom in on a portion of a wider view display (suchas the view shown in FIG. 12) or zoom out from a narrower view (such asshown in FIG. 13). In addition, the user may use the user input deviceto rotate the view of a given display in any or all three dimensions,thereby allowing the user to manipulate the display presented to obtainwhatever view best presents the log data 1230, 1240, 1215, and 1220 tothe user. Moreover, the user may use the user input device connected tothe downhole display system to adjust the display of the log data as theuser navigates along the well path, so that the display presentsrelevant log data 1215, 1220, 1230, and 1240 for segments correspondingto a given position on the well path 1200 selected by the user. Becausethe user may move along the well path slowly or quickly as the user maydesire, the display will also change and adjust the display of the logsegments slowly or quickly, respectively.

In FIG. 14, the MD log 1240 is provided as the reference log alongsidethe wellbore plot 1200. In addition, the measured wellbore log portions1215 and 1220 may overlap and may be both shown in a single color (e.g.,green) to indicate that they have been correlated in a satisfactoryfashion.

FIGS. 15 and 16 depict an example of the downhole display in anotherembodiment. Specifically, FIGS. 15 and 16 depict a drilled well boreholetrajectory 1500 alongside a planned well trajectory 1510. The welltrajectories 1500 and 1510 are depicted in a channel or passageway forviewing clarity. It is noted that other contexts or environments may beused for the background of the well trajectories. The relative distancebetween the two trajectories 1500 and 1510 can be indicated at a givenlocation using a rectangular display of areas of uncertainty ortrajectory error, or with reference to the planned target location. Indifferent embodiments, either the drilled wellbore 1500 or the referencewellbore 1510 may be centered on the rectangular display, such as whenthe rectangular display regions 1520, 1525, and 1530 represent differentzones of acceptable performance for locating the drilled wellbore 1500relative to the planned or target location 1510. For example, therectangle 1530 may indicate that the drilled well trajectory 1500 iswithin an acceptable deviation from the reference well trajectory 1510,and may be colored green on the display to indicate that the locationwithin that rectangle is acceptable. The rectangle 1525 may indicate ahigher level of variance from the reference well trajectory 1510 than isdesired or may serve as a potential warning that the actual wellbore maybe about to exit an acceptable location relative to the planned wellbore1510. The rectangle 1525 may be colored yellow on the display to soindicate. The outer rectangle 1520 may indicate borderline unacceptablelevels of variance from the reference well trajectory 1510, and may bedisplayed as red to so indicate. It is noted that in some embodiments,ellipsoids of uncertainty rather than rectangles for target locationsmay be used. It is also noted that, in addition to or instead ofdifferent colors, the display could alter the target window orellipsoids of uncertainty by displaying them in different shapes, sizes,with labels, one or more flashing, different levels of brightness, andso forth.

In FIGS. 15 and 16, additional information is depicted using elements inthe display. For example, alongside the drilled well trajectory 1500 atcertain intervals a white fin 1550 is shown that indicates an amplitudeand direction of a formation drift force that the geological formationexerts on the rotating drill bit. Next to the white fin 1550, severalsmaller needles 1560 emerging from the drilled well trajectory 1500indicate toolface values that have been measured. Other values, such asnumerical values for toolface or other annotations can also be displayedalong the well trajectories.

In the examples provided herein, it should be noted that the displayshave been presented in a three-dimensional fashion in the sense thatFIGS. 12-16 reflect depth as well as height and width. In addition, thedisplays as illustrated in FIGS. 12-16 can be manipulated in any or allthree dimensions to present varying views that reflect three dimensions.However, it is noted that the downhole display system can be programmedand can use data to provide two-dimensional displays if desired, andalso can be programmed and can use data to provide other views ifdesired, such as are available with virtual reality systems. Forexample, the display could be provided by the downhole display system toa user using via VR goggles and the user could then virtually navigatethe wellbore by various means, such as virtually walking along thewellbore path, virtually manipulating the wellbore with a hand, or byusing gestures or motions as input to the system to move the displaypresented via the VR goggles.

The above disclosed subject matter is to be considered illustrative, andnot restrictive, and the appended claims are intended to cover all suchmodifications, enhancements, and other embodiments which fall within thetrue spirit and scope of the present disclosure. Thus, to the maximumextent allowed by law, the scope of the present disclosure is to bedetermined by the broadest permissible interpretation of the followingclaims and their equivalents, and shall not be restricted or limited bythe foregoing detailed description.

What is claimed is:
 1. A computer system for displaying downholeinformation for a wellbore in three dimensions, the computer systemcomprising: a processor; a display coupled to the processor; a userinput device coupled to the processor; and a memory coupled to theprocessor, wherein the memory comprises instructions executable by theprocessor, wherein the instructions comprise instructions for: receivingfirst well log data associated with a reference well; receivingtrajectory information associated with a wellbore; receiving second welllog data associated with the wellbore; generating a first correlation ofa first segment of the second well log data associated with a firstlocation of the wellbore with a corresponding first segment of the firstwell log data; providing on the display a first display of the wellborebased on the trajectory information and the first correlation of thefirst segment of the first well log data and the first segment of thesecond well log data, wherein the first correlation is projected alongthe wellbore on the first display; and responsive to an input from theuser input device, at least one of: adjusting the first display of thefirst correlation and providing a second display of the adjusted firstdisplay, and providing a display of a second correlation of a secondsegment of the first well log data with a corresponding second segmentof the second well log data, wherein the second segment of the secondwell log data is associated with a second location of the wellbore. 2.The system according to claim 1, wherein the user input device comprisesa video game controller.
 3. The system according to claim 1, wherein theinstructions further comprise instructions for: responsive to a userinput, generating and providing a plurality of displays, eachcorresponding to one of a plurality of locations along the wellbore,wherein the user input is associated with a selection of the pluralityof locations, and wherein each of the displays comprises a display ofthe trajectory of at least a portion of the wellbore and a plurality ofcorrelations of a plurality of segments of the first well log data andthe second well log data, wherein each of the plurality of segmentscorresponds to one of the plurality of locations along the wellbore. 4.The system according to claim 3, wherein the plurality of displayscomprise a plurality of three-dimensional (3D) displays.
 5. The systemaccording to claim 1, wherein each of the first display and the seconddisplay comprise a 3D display.
 6. The system according to claim 1,wherein each of the first display and the second display comprise atwo-dimensional display.
 7. The system according to claim 3, wherein theinstructions further comprise instructions for: responsive to the userinput, adjusting the first display in any one of three dimensions toprovide an adjusted display corresponding to the user input.
 8. Thesystem according to claim 1, wherein the instructions further compriseinstructions for: receiving well plan data comprising a target wellpath; comparing the trajectory information associated with the wellboreto the target well path; and providing a 3D display of the target wellpath.
 9. The system according to claim 8, wherein the instructionsfurther comprise instructions for: generating and providing a visualindication of a confidence level associated with the trajectoryinformation of the wellbore.
 10. The system according to claim 1,wherein the first display further comprises the first segment of thefirst well log data in a first color and the first segment of the secondwell log data in a second color.
 11. The system according to claim 10,wherein the first color or the second color are associated with aconfidence level associated with the first correlation.
 12. A computersystem for displaying downhole information for a wellbore, the computersystem comprising: a processor; a display coupled to the processor; auser input device coupled to the processor, wherein the user inputdevice comprises a video game controller having an accelerometer or agyroscope and adapted to provide a tactile sensation to a user thereof;and a memory coupled to the processor, wherein the memory comprisesinstructions executable by the processor, wherein the instructionscomprise instructions for: receiving first well log data associated witha reference well; receiving trajectory information associated with awellbore; receiving second well log data associated with the wellbore;providing on the display a first display of the wellbore based on thetrajectory information; and responsive to an input from the user inputdevice, at least one of: adjusting the first display and providing asecond display of the adjusted first display, and adjusting a display ofa correlation of a first segment of the first well log data with acorresponding first segment of the second well log data to provide thesecond display, wherein the correlation is projected along the wellboreon the second display, and wherein the second display is associated witha second location along the wellbore and the first display is associatedwith a first location along the wellbore.
 13. The computer systemaccording to claim 12, wherein the instructions further compriseinstructions for generating the tactile sensation corresponding to aphysical movement from the first location along the wellbore to thesecond location along the wellbore.
 14. The computer system according toclaim 13, wherein the instructions further comprise instructions foradjusting the first display in any one of three dimensions responsive touser input provided to the user input device.
 15. The computer systemaccording to claim 14, wherein the first display comprises athree-dimensional display.
 16. The computer system according to claim15, wherein the first display comprises a target window at a locationalong the wellbore, wherein the target window comprises a plurality ofregions, each of which is displayed in a different color, shape, size,or brightness.
 17. A computer system for displaying informationassociated with a wellbore, the computer system comprising: a processor;a memory coupled to the processor, wherein the memory comprisesinstructions executable by the processor, wherein the instructionscomprise instructions for: receiving input from a user input device,wherein the user input device comprises a video game controller;receiving first well log data associated with a reference well;receiving trajectory information associated with a wellbore; receivingsecond well log data associated with the wellbore; providing displaydata for a first display of the wellbore based on the trajectoryinformation; and responsive to the input from the user input device, atleast one of: adjusting the first display and providing a second displayof the adjusted first display, and adjusting a display of a correlationof a first segment of the first well log data with a corresponding firstsegment of the second well log data to provide the second display,wherein the correlation is projected along the wellbore on the seconddisplay, and wherein the second display is associated with a secondlocation along the wellbore and the first display is associated with afirst location along the wellbore, and switching from the first displayof the wellbore to the second display that comprises the adjusted firstdisplay of the wellbore and a display of another wellbore.
 18. Thecomputer system according to claim 17, wherein the instructions forswitching from the first display of the wellbore to the second displayfurther comprise instructions for the second display that comprises thewellbore and a plurality of other wellbores.
 19. The computer systemaccording to claim 18, wherein the instructions for switching from thefirst display of the wellbore to the second display further compriseinstructions for adjusting the first display responsive to the input,thereby allowing a user to adjust the display of the wellbore and theplurality of other wellbores so as to navigate through the earth or toview the wellbore and the plurality of other wellbores from overhead.20. The computer system according to claim 17, wherein the instructionsfurther comprise instructions for displaying at least one geologicalformation relative to the wellbore.
 21. The computer system according toclaim 17, wherein the instructions further comprise instructions forproviding a display of a target window relative to the wellbore.
 22. Thecomputer system according to claim 21, wherein the target windowcomprises a plurality of regions, each of which is displayed in adifferent size, shape, color, brightness, or pattern.